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Defect States in SiC/GaN- and SiC/AlGaN/GaN- Heterostructures Characterized by Admittance and Photocurrent Spectroscopy

Published online by Cambridge University Press:  13 June 2014

H. Witte
Affiliation:
Institute of Experimental Physics, University of Magdeburg, PO Box 4120, 39016 Magdeburg, Germany
A. Krtschil
Affiliation:
Institute of Experimental Physics, University of Magdeburg, PO Box 4120, 39016 Magdeburg, Germany
M. Lisker
Affiliation:
Institute of Experimental Physics, University of Magdeburg, PO Box 4120, 39016 Magdeburg, Germany
J. Christen
Affiliation:
Institute of Experimental Physics, University of Magdeburg, PO Box 4120, 39016 Magdeburg, Germany
F. Scholz
Affiliation:
4th Institute of Physics, University of Stuttgart, D- 70550 Stuttgart, Germany
J. Off
Affiliation:
4th Institute of Physics, University of Stuttgart, D- 70550 Stuttgart, Germany

Abstract

Deep defect levels in n-type GaN/AlN/6H-SiC- and GaN/AlGaN/6H-SiC- heterostructures grown by Metallorganic Vapor Phase Epitaxy were analyzed by Thermal and Optical Admittance and Photocurrent Spectroscopy. The various thermal and optical transitions in the spectra originating from both the Schottky contact as well as the GaN/SiC- and AlGaN/GaN-heterojunctions were separated. This was achieved by variation of the modulation frequency, the use of different contact arrangements and by comparison with reference spectra from GaN/Sapphir samples and SiC substrates. In the GaN/AlGaN/SiC structures a bias voltage dependent peak shift was found which is correlated to an interface related defect distribution. In additionally to, SiC related defects, defect-band-transitions involving defects with transition energies at 2.2eV, 1.85eV, EG-(470±40) meV and EG-(65-95) meV were found for the GaN layer.

Type
Research Article
Copyright
Copyright © 1999 Materials Research Society

Introduction

Besides their optoelectronic potential, GaN and their related compounds are very important for high-frequency, high-power and high- temperature electronic devices /Reference Mohammad and Morkoc1/. Especially, heterostructures based on GaN and AlGaN on SiC- substrate are main parts of some novel devices such as MESFET's, MODFET's, bipolar transistors /Reference Mohammad and Morkoc1/, UV-detectors /Reference Osinsky, Gangopadhya, Lim, Anwar, Khan, Kuksenkov and Temkin2/, LED's and laser diodes /Reference Mohammad and Morkoc1/. Defects states in the layers and in the interface regions influence both optical /Reference Torvik, Qiu, Leksono and Pankove3/ and electrical /Reference Torvik, Leksono, Pankove, VanZeghbroeck, Ng and Moustakas4/ properties. For example, in GaN / p-type SiC -structures the photoluminescence and electroluminescence spectra show defect related transitions /Reference Torvik, Qiu, Leksono and Pankove3/ which cause tunneling-assisted currents described in /Reference Torvik, Leksono, Pankove, VanZeghbroeck, Ng and Moustakas4/. Furthermore, in GaN / p-type SiC heterojunctions, indications on interface defect states were found by C-V-characteristics /Reference Kusnetzov, Gubenco, Nicolaev, Melnik, Blashenkov, Nikita and Dmitriev5/ and by admittance spectroscopy /Reference Krtschil, Witte, Lisker, Christen, Birkle, Einfeldt, Hommel, Topf and Meyer6/.

In GaN/AlGaN pin-structures on SiC-substrates, Mg-related recombination centers were found with temperature dependent dark current measurements and with current-DLTS having activation energies of 0.191eV and 0.207eV, respectively /Reference Dmitriev7/.

The aim of this paper is to present evidences for defects and localize these traps in the layers and interfaces using Thermal and Optical Admittance Spectroscopy. We show, that defect spectra of heterostructures can be led back to those of the corresponding single layers on sapphire. We were able to separate the different heterojunctions by variation of the modulation frequency and the contact arrangement of the samples.

These investigations provide the for the determination of the capacitance and conduction values of the individual parts of the heterostructure. Only with these knowledge an calculation of the concentrations of the different traps would be possible. The quantitative analysis will be the aim of future work.

Experimental

The first group of samples consist of a n-type 6H-SiC- substrate (carrier concentration of about 1.5*1018cm−3), a 17nm thick AlN nucleation layer followed by a 1µm thick, nominally undoped, n-type GaN layer. The second kind of heterostructures is based on the same SiC substrate followed by a 500nm thick AlGaN buffer layer ( [Al] 43-47%). The undoped GaN top layer is 500nm thick. All layers were grown by Metallorganic Vapor Phase Epitaxy (MOVPE) at a growth temperature of 1000°C. For reference measurements we investigated various undoped GaN layers deposited with the same MOVPE equipment on sapphire substrates as well as the SiC substrate itself.

The samples were cleaned with organic solutions and etched in HF (SiC) and ammonium hydroxyd (GaN) solution. Ohmic contacts were formed by sputtering of Ni on SiC- substrate and by evaporation of Al- layer on GaN followed by an annealing process at 7000C for 10 min. in an inert gas atmosphere. The Schottky contacts were realized by sputtering of a 100nm thick Ptlayer having a diameter of 1mm. Sandwich arrangement with the ohmic contact on the SiC substrate and the Schottky contact on the GaN side as well as coplanar arrangement consisting of both contacts on the GaN layer were used. All GaN on sapphire samples are contacted in coplanar arrangement. For further reference measurements, contacts on the SiC sample were deposited in sandwich arrangement using a Pt Schottky contact. All Schottky contacts show rectifying behavior up to a frequency range of about 100kHz - 500kHz.

Thermal Admittance Spectroscopy (TAS) measurements were carried out in the temperature region between 78K and 450K using a high precision LCR-meter (HP 4284A) at modulation frequencies between 20Hz and 1MHz under zero bias conditions. The experimental set up and the evaluation method is described in detail in /Reference Barbolla, Duenas and Bailon8/. For the Optical Admittance Spectroscopy (OAS) an optical-electrical cryostat was used for measurements at temperatures between 78 and 295K. A monochromator illumination system yielded monochromatic light with wave length between 300nm and 3000nm (see also /Reference Krtschil, Lisker, Witte, Christen, Birle, Einfeldt and Hommel9/).

Results and Discussion

In TAS spectra of all heterostructures with sandwich contacts a peak is observed at a temperature of about Tmax=85K at 1MHz. A peak with identical Tmax is also found in the reference spectrum of the n-type SiC sample (thermal activation energy (61±5)meV, see Table 1). Thus, we conclude that these peaks are caused by the same defect level. The origin of this electron trap is probably the N-donor in 6H-SiC /Reference Pensl and Troffer10/. This behavior corresponds very well with TAS investigations of n-type GaN layers grown by LPCVD on n-type 6H-SiC- substrates described in /Reference Krtschil, Witte, Lisker, Christen, Birkle, Einfeldt, Hommel, Topf and Meyer6/.

Table I : Summary of observed thermal activation energies and peak maximum temperatures of GaN/AlN/Sapphire-layers and in heterostructures measured with TAS and with OAS detected defect-band-transition energies of various layer structures. A band gap energy of EG= 3.44eV at 295K was used according to /Reference Monemar15/. The meaning of the abbreviations is : NBG near band gap region; BB blue band region, YB yellow band region and SiC-peak ; DT deep defect-band transition.

method GaN/AlN/Sapphire GaN/AlN/SiC GaN/AlGaN/SiC n-type SiC
TAS (130-170) meV
(276±28) meV
(320±24) meV
peak at 85K peak at 85K peak at 85K (61±5)meV
OAS /NBG (65-95)meV below gap 18meV below gap 3.42eV -
OAS / BB 290; 370 , 460 and 760meV below gap (450-510) meV below gap -
OAS / YB+SiC 2.2eV 2.22-2.26 eV - 2.25eV
OAS / DT 1.82eV 1.87eV - -

In contrary, three electron traps with activation energies between 130 meV and 320meV were found in the reference samples consisting of GaN/AlN/Sapphire layers using TAS (see also Table I). These defects are well known from the literature, for example in /Reference Krtschil, Witte, Lisker, Christen, Birkle, Einfeldt, Hommel, Topf and Meyer6/,/Reference Hacke and Okushi13/ and /Reference Götz, Johnson, Bour, Chen, Liu, Kuo and Imler14/ detected by DLTS and TAS in MOVPE and MBE grown material. The discrepancy between the detection of defects in the heterostructures and the reference samples shows, that the high doping concentration in the SiC substrate dominates the TAS signals of the heterostructures strongly.

In GaN/AlGaN/SiC-heterostructures a bias voltage dependent shifting peak at frequencies between 0.5 and 2.5*105 1/s is observed by AS in reverse direction, as shown in Fig.1. The peak height remains constant at about (2-3) nF. Because of the conductance of the SiC-substrate we used the Kramers-Kronig transformation of the admittance data to eliminate the series resistance/Reference Leon, Martin, Santamaria, Skarp, Gonzalez-Diaz and Sanchez-Queseda11/. A bias dependent shift of an AS peak position is well known from Si/SiO2- interface defect distributions ( for example see /Reference Nicolian and Brews12/). We conclude, that this peak is caused either by an intermediate layer in one of the heterojunctions, gradients of defect states in the interface regions, or interface defect state distributions. A similar behavior is also observed in n-type GaN (LPCVD grown) /p-type SiC heterostructures (for more details see /Reference Krtschil, Witte, Lisker, Christen, Birkle, Einfeldt, Hommel, Topf and Meyer6/).

Fig. 1: Transformed Conductance /Reference Leon, Martin, Santamaria, Skarp, Gonzalez-Diaz and Sanchez-Queseda11/ as a function of frequency of the GaN/AlGaN/SiC heterostructure for different reverse bias voltages. The insert shows the shift of the peak maximum with increasing bias voltage.

The TAS and AS results clearly show, that all components of the heterostructures, i.e. the SiC substrate, the AlGaN and GaN layers, the corresponding heterojunctions as well as the Schottky contact on the GaN top layers contribute to the measured signals.

In order to separate these different parts of the heterostructures we compare OAS spectrum of the GaN/AlN/SiC structure with OAS spectra of the SiC-substrate and of GaN layers on sapphire (Fig. 2). The spectrum of the heterostructures in coplanar contact arrangement shows the same structure as the spectra of GaN on sapphire. However, in sandwich arrangement the heterostructures show the SiC-spectrum, leading to the conclusion that the GaN/SiC-spectrum with sandwich contacts is influenced by the SiC-side of the heterojunction and the coplanar arrangement is dominated by the Schottky contact on the GaN layer, respectively. All defect-band transitions in the OAS spectra are summarized in Table 1 together with TAS results.

Fig. 2: Optical Admittance Spectra of different GaN structures. 1- GaN on sapphire; 2-GaN/AlN/SiC with coplanar contacts; 3- GaN/AlN/SiC with sandwich contacts; 4- 6H-SiC.

Another method to separate the various parts of the structures is based on the variation of the modulation frequency, visualized in Fig. 3. In the GaN/AlGaN/SiC heterostructures the near band gap region (NBG) of AlGaN and GaN below 3.4eV occurs. With increasing frequency the Schottky contact on the GaN layer breaks down, the NBG peaks vanish and the SiC-side of the heterojunction (peak at 2.65eV) dominates the OAS spectrum.

Fig. 3: Optical Admittance Spectra of an GaN/Al0.43Ga0.57N/SiC heterostructure for different modulation frequencies. The peak heights of the both peaks at 3.4eV (GaN) and 2.56eV (SiC) are plotted as a function of the frequency in the insert.

Using coplanar contact arrangement and low frequencies OAS spectra of the heterostructures which dominated by defects of the GaN layer were measured. The defect-to-band transitions found are shown in Table I.

In the OAS spectra of the GaN/Al/SiC we have to distinguish between the near band gap region involving defects-to-(opposite) band transitions, the blue band originating from transitions from deep defects to the opposite band, the yellow band which is comparable to the yellow luminescence band and the deep defect at 1.85eV. All, these defects were also found in MBE grown GaN (seen /Reference Krtschil, Witte, Lisker, Christen, Birkle, Einfeldt, Hommel, Topf and Meyer6/ and /Reference Krtschil, Lisker, Witte, Christen, Birle, Einfeldt and Hommel9/) as well as in MOVPE grown GaN layers on sapphire (see /Reference Hacke and Okushi13/ and /Reference Götz, Johnson, Bour, Chen, Liu, Kuo and Imler14/).

Differences between the OAS spectra of the GaN/AlN/Sapphire sample and the GaN/AlN/SiC heterostructures show up in the near band region. For the GaN/AlN/SiC-heterostructures shallower transitions (EG-18meV) were observed in comparison of the GaN/AlN/Sapphire reference samples (EG-(65-95)meV). One reason may be a dominance of shallower defects, for example the Si level, in the GaN layer on SiC.

The similarities in the OAS spectra between the GaN/AlN/SiC heterostructure and the reference samples on Sapphire show that the substrate material influences not the occurrence of these defects qualitative. Otherwise, the quantitative analysis of these defects will be make in the future.

In the OAS spectra of the GaN/AlGaN/SiC structures only the near band gap (NBG) peak consisting of the GaN (360nm) and the AlGaN (290nm) layers occurs. Other defect-band transitions were not observed. A corresponding PC spectrum on the reference sample AlGaN/AlN/Sapphire shows only the near band gap peak similar to the spectra of the heterostructures. We assume this behavior in the OAS spectra is caused by the high resistivity of the AlGaN layer within the heterostructures.

In summary, n-type GaN/AlN/6H-SiC- and n-type GaN/AlGaN/6H-SiC-heterostructures were characterized for defect levels in the GaN-layers using thermal and optical admittance spectroscopy. Different contact arrangements, variation of modulation frequency and comparison with spectra of GaN/Sapphire and SiC samples enables us to assign the signals to the individual junctions. A defect distribution correlated with the interface between GaN and SiC is found by admittance spectroscopy. Using OAS some deep defect- band-transition in the GaN layer of the GaN/Al/SiC heterostructure were detected.

Acknowledgments

This work was financially supported by the Deutsche Forschungsgemeinschaft under contract number WI 1619/1-1 and by the Kultusministerium Sachsen-Anhalt contract number 002KD1997.

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Figure 0

Table I : Summary of observed thermal activation energies and peak maximum temperatures of GaN/AlN/Sapphire-layers and in heterostructures measured with TAS and with OAS detected defect-band-transition energies of various layer structures. A band gap energy of EG= 3.44eV at 295K was used according to /15/. The meaning of the abbreviations is : NBG near band gap region; BB blue band region, YB yellow band region and SiC-peak ; DT deep defect-band transition.

Figure 1

Fig. 1: Transformed Conductance /11/ as a function of frequency of the GaN/AlGaN/SiC heterostructure for different reverse bias voltages. The insert shows the shift of the peak maximum with increasing bias voltage.

Figure 2

Fig. 2: Optical Admittance Spectra of different GaN structures. 1- GaN on sapphire; 2-GaN/AlN/SiC with coplanar contacts; 3- GaN/AlN/SiC with sandwich contacts; 4- 6H-SiC.

Figure 3

Fig. 3: Optical Admittance Spectra of an GaN/Al0.43Ga0.57N/SiC heterostructure for different modulation frequencies. The peak heights of the both peaks at 3.4eV (GaN) and 2.56eV (SiC) are plotted as a function of the frequency in the insert.